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Steel Bridge Design Handbook
November 2012
U.S.Department of Transportation
Federal Highway Administration
Design Example 5:Three-Span Continuous
Horizontally Curved Composite
Steel Tub-Girder BridgePublication No. FHWA-IF-12-052 - Vol. 25
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i
Notice
This document is disseminated under the sponsorship of the U.S. Department of Transportation inthe interest of information exchange. The U.S. Government assumes no liability for use of the
information contained in this document. This report does not constitute a standard, specification,
or regulation.
Quality Assurance Statement
The Federal Highway Administration provides high-quality information to serve Government,industry, and the public in a manner that promotes public understanding. Standards and policies
are used to ensure and maximize the quality, objectivity, utility, and integrity of its information.FHWA periodically reviews quality issues and adjusts its programs and processes to ensure
continuous quality improvement.
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Steel Bridge Design Handbook
Design Example 5: Three-Span
Continuous Horizontally CurvedComposite Steel Tub-Girder Bridge
Publication No. FHWA-IF-12-052 Vol. 25
November 2012
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Technical Report Documentation Page1. Report No.FHWA-IF-12-052 Vol. 25
2. Government Accession No. 3. Recipients Catalog No.
4. Title and SubtitleSteel Bridge Design Handbook Design Example 5: Three-Span
Continuous Horizontally Curved Composite Steel Tub-Girder Bridge
5. Report DateNovember 2012
6. Performing Organization Code
7. Author(s)Brandon Chavel, Ph.D., P.E. and Julie Rivera, P.E.
8. Performing Organization Report No.
9. Performing Organization Name and AddressHDR Engineering, Inc.
11 Stanwix Street
Suite 800
Pittsburgh, PA 15222
10. Work Unit No.
11. Contract or Grant No.
12. Sponsoring Agency Name and AddressOffice of Bridge Technology
Federal Highway Administration
1200 New Jersey Avenue, SE
Washington, D.C. 20590
13. Type of Report and Period CoveredTechnical Report
March 2011 November 2012
14. Sponsoring Agency Code
15. Supplementary Notes
16. AbstractTub girders, as closed-section structures, provide a more efficient cross section for resisting torsion than I-girders, which is
especially important in horizontally curved highway bridges. The increased torsional resistance of a closed composite steel tub
girder also results in an improved lateral distribution of live loads. For curved bridges, warping, or flange lateral bending,
stresses are lower in tub girders, when compared to I-girders, since tub girder carry torsion primarily by means of St. Venant
torsional shear flow around the perimeter of their closed sections, whereas I-girders have very low St. Venant torsional stiffness
and carry torsion primarily by means of warping.
This design example illustrates the design calculations for a curved steel tub girder bridge, considering the Strength, Service,
fatigue and Constructibility Limits States in accordance with the AASHTO LRFD Bridge Designs specifications. Calculations
are provided for design checks at particular girder locations, a bolted field splice design, an internal pier diaphragm design, and atop flange lateral bracing member design.
17. Key WordsSteel Tub Girder Bridge, Steel Box Girder Bridge, LRFD,
Bolted Field Splice, Top Flange Lateral Bracing, Box
Girder Distortional Stresses
18. Distribution StatementNo restrictions. This document is available to the public through
the National Technical Information Service, Springfield, VA
22161.
19. Security Classif. (of this report)Unclassified
20. Security Classif. (of this page)Unclassified
21. No of Pages 22. Price
Form DOT F 1700.7 (8-72) Reproduction of completed pages authorized
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Steel Bridge Design Handbook:
Design Example of a Three-Span Continuous Curved
Composite Tub-Girder Bridge
TABLE OF CONTENTS
TABLE OF CONTENTS ................................................................................................................ vLIST OF FIGURES ........................................................................................................................ xLIST OF TABLES ......................................................................................................................... xiFOREWORD ................................................................................................................................ xii1.0 INTRODUCTION ................................................................................................................. 12.0 OVERVIEW OF LRFD ARTICLE 6.11 ............................................................................... 33.0 DESIGN PARAMETERS ..................................................................................................... 54.0 GENERAL STEEL FRAMING CONSIDERATIONS ......................................................... 7
4.1 Span Arrangement ........................................................................................................... 74.2 Field Section Sizes ........................................................................................................... 94.3 Bridge Cross Section and Girder Spacing ....................................................................... 94.4 Internal and External Cross-Frame Bracing .................................................................. 104.5 Diaphragms at the Supports ........................................................................................... 124.6 Top Flange Lateral Bracing ........................................................................................... 12
5.0 FINAL DESIGN .................................................................................................................. 155.1 AASHTO LRFD Limit States ........................................................................................ 15
5.1.1 Strength Limit State .............................................................................................. 155.1.2 Service Limit State ................................................................................................ 155.1.3 Fatigue and Fracture Limit State........................................................................... 155.1.4 Extreme Event Limit State .................................................................................... 165.1.5 Constructibility ..................................................................................................... 16
5.2 Loads .............................................................................................................................. 165.2.1 Dead Load ............................................................................................................. 165.2.2 Deck Placement Sequence .................................................................................... 17
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5.2.3 Live Load .............................................................................................................. 195.3 Centrifugal Force Computation ..................................................................................... 195.4 Load Combinations ........................................................................................................ 23
6.0 ANALYSIS .......................................................................................................................... 256.1 Three-Dimensional Finite Element Analysis ................................................................. 25
6.1.1 Bearing Orientation and Arrangement .................................................................. 266.1.2 Live Load Analysis ............................................................................................... 27
6.2 Analysis Results ............................................................................................................. 287.0 DESIGN ............................................................................................................................... 36
7.1 Girder Section Proportioning ......................................................................................... 367.1.1 Girder Web Depth ................................................................................................. 387.1.2 Cross-section Proportions ..................................................................................... 39
7.2 Section Properties .......................................................................................................... 407.2.1 Section G2-1: Span 1 Positive Moment Section Properties.................................. 41
7.2.1.1 Effective Width of Concrete Deck ......................................................... 427.2.1.2 Elastic Section Properties: Section G2-1 ............................................... 437.2.1.3 Plastic Moment Neutral Axis: Section G2-1 .......................................... 45
7.2.2 Section G2-2: Support 2 Negative Moment Section Properties ........................... 457.2.2.1 Elastic Section Properties: Section G2-2 ............................................... 46
7.2.3 Check of Minimum Negative Flexure Concrete Deck Reinforcement (Article6.10.1.7) ............................................................................................................................ 49
7.3 Girder Check: Section G2-1, Constructibility (Article 6.11.3) ...................................... 507.3.1 Deck Overhang Bracket Load ............................................................................... 517.3.2 Flange Lateral Bending Due to Web Shear .......................................................... 527.3.3 Flange Lateral Bending Due to Curvature ............................................................ 537.3.4 Top Flange Lateral Bending Amplification .......................................................... 547.3.5 Flexure (Article 6.11.3.2)...................................................................................... 55
7.3.5.1 Top Flange.............................................................................................. 567.3.5.2 Bottom Flange ........................................................................................ 60
7.4 Girder Check: Section G2-1, Service Limit State (Article 6.11.4) ................................ 617.4.1 Permanent Deformations (Article 6.10.4.2) .......................................................... 61
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7.4.2 Web Bend-Buckling.............................................................................................. 627.5 Girder Check: Section G2-1, Fatigue Limit State (Article 6.11.5) ................................ 62
7.5.1 Special Fatigue Requirements for Webs ............................................................... 647.6 Girder Check: Section G2-1, Strength Limit State (Article 6.11.6) .............................. 65
7.6.1 Flexure (Article 6.11.6.2)...................................................................................... 657.6.1.1 Top Flange Flexural Resistance in Compression ................................... 687.6.1.2 Bottom Flange Flexural Resistance in Tension ..................................... 697.6.1.3 Concrete Deck Stresses .......................................................................... 70
7.7 Girder Check: Section G2-2, Constructibility (Article 6.11.3) ...................................... 707.7.1 Flexure (Article 6.11.3.2)...................................................................................... 70
7.7.1.1 Top Flange.............................................................................................. 727.7.1.2 Bottom Flange ........................................................................................ 737.7.1.3 Shear (Article 6.11.3.3) .......................................................................... 77
7.8 Girder Check: Section G2-2, Service Limit State (Article 6.11.4) ................................ 797.8.1 Permanent Deformations (Article 6.10.4.2) .......................................................... 797.8.2 Web Bend-Buckling.............................................................................................. 79
7.9 Girder Check: Section G2-2, Fatigue Limit State (Article 6.11.5) ................................ 837.9.1 Cross-section Distortion Stresses .......................................................................... 84
7.10 Girder Check: Section G2-2, Strength Limit State (Article 6.11.6) .............................. 937.10.1 Flexure (Article 6.11.6.2)...................................................................................... 937.10.2 Top Flange ............................................................................................................ 967.10.3 Bottom Flange ....................................................................................................... 96
7.10.3.1 Cross-section Distortion Stresses ....................................................... 1037.10.4 Shear (Article 6.11.6.3) ....................................................................................... 103
7.10.4.1 Interior Panel (Article 6.10.9.3.2) ...................................................... 1047.11 Bottom Flange Longitudinal Stiffener ......................................................................... 1067.12 Internal Pier Diaphragm Design .................................................................................. 108
7.12.1 Web Shear Check ................................................................................................ 1097.12.1.1 Noncomposite Shear Force ................................................................ 1097.12.1.2 Composite Shear Force ...................................................................... 1117.12.1.3 Total Factored Shear Force ................................................................ 111
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7.12.1.4 Check of Internal Diaphragm Web .................................................... 1127.12.2 Bearing Stiffeners ............................................................................................... 113
7.12.2.1 Bearing Resistance ............................................................................. 1157.12.2.2 Axial Resistance ................................................................................. 115
7.13 Top Flange Lateral Bracing Design ............................................................................. 1177.14 Bolted Field Splice Design .......................................................................................... 124
7.14.1 Bolt Resistance for the Service Limit State and Constructibility ....................... 1277.14.2 Bolt Resistance for the Strength Limit State....................................................... 128
7.14.2.1 Bolt Shear Resistance ......................................................................... 1287.14.2.2 Bearing Resistance on Connected Material ....................................... 129
7.14.3 Constructibility Checks ....................................................................................... 1307.14.3.1 Constructibility Check of Top Flange Splice Bolts ........................... 1317.14.3.2 Constructibility Check of Bottom Flange Splice Bolts ...................... 1327.14.3.3 Constructibility Check of Web Splice Bolts ...................................... 134
7.14.4 Service Limit State .............................................................................................. 1377.14.4.1 Service Limit State Check of Top Flange Splice Bolts ...................... 1397.14.4.2 Service Limit State Check of Bottom Flange Splice Bolts ................ 1407.14.4.3 Service Limit State Check of Web Splice Bolts ................................ 142
7.14.5 Strength Limit State ............................................................................................ 1427.14.5.1 Positive Flexure Strength Limit State Design Forces ........................ 1447.14.5.2 Negative Flexure Strength Limit State Design Forces ....................... 1467.14.5.3 Summary of Flexure Strength Limit State Design Forces ................. 1487.14.5.4 Strength Limit State Check of Top Flange Splice Bolts .................... 1487.14.5.5 Strength Limit State Check of Bottom Flange Splice Bolts............... 1487.14.5.6 Strength Limit State Check of Web Splice Bolts ............................... 1507.14.5.7 Strength Limit State Check of Top Flange Splice Plates ................... 1557.14.5.8 Strength Limit State Check of Top Flange Splice Plates - Bearing ... 1587.14.5.9 Strength Limit State Check of Bottom Flange Splice Plates ............. 1597.14.5.10 Strength Limit State Check of Bottom Flange Splice Plates - Bearing 1627.14.5.11 Strength Limit State Check of Web Splice Plates ............................ 164
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7.14.5.12 Strength Limit State Check of Web Splice Bearing on Girder Web 1677.14.5.13 Strength Limit State Check of Web Splice Plates Block Shear .... 167
8.0 SUMMARY OF DESIGN CHECKS AND PERFORMANCE RATIOS ......................... 1699.0 REFERENCES .................................................................................................................. 171
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LIST OF FIGURES
Figure 1 Framing Plan of the Tub Girder Bridge (all lengths shown are taken along the
centerline of the bridge) .................................................................................................................. 8Figure 2 Cross Section of the Tub Girder Bridge [2] .................................................................. 10Figure 3 Plan View of a Warren-type truss lateral bracing system [1] ........................................ 13Figure 4 Plan View of a Pratt-type truss lateral bracing system [1] ............................................ 14Figure 5 Diagram showing deck placement sequence ................................................................. 18Figure 6 Vehicular Centrifugal Force Wheel-Load Reactions .................................................... 20Figure 7 Effects of Superelevation of the Wheel-Load Reactions .............................................. 22Figure 8 Unit Wheel Load Factors due to Combined Effects of Centrifugal Force and
Superelevation............................................................................................................................... 23Figure 9 Girder G2 elevation ....................................................................................................... 37Figure 10 Sketch of Tub-Girder CrossSection at Section G2-1 ................................................ 42Figure 11 Moment of Inertia of an Inclined Web ........................................................................ 43Figure 12 Sketch of Tub-Girder CrossSection at Section G2-2 ................................................ 46Figure 13 Deck Overhang Bracket Loading ................................................................................ 51Figure 14 Effective Width of Web Plate, do, Acting with the Transverse Stiffener .................... 86Figure 15 Concentrated Torque at Mid-panel on Continuous Beam - Distortional Bending Stress
at Load (DGBGB Figure A6 [11]) ................................................................................................ 91Figure 16 Concentrated Torque at Mid-panel on Continuous Beam Normal Distortional
Warping Stress at Mid-panel (DGBGB Table A9 [11]) ............................................................... 92Figure 17 Sketch of the Internal Diaphragm and Bearing Locations ........................................ 108Figure 18 Illustration for the computation of the shear in the internal diaphragms due to St.
Venant torsion and tub girder flexure ......................................................................................... 111Figure 19 Bolt Pattern for the Top Flange Field Splice ............................................................. 125Figure 20 Bolt Pattern for the Bottom Flange Field Splice, shown inside the tub girder lookingdown at the bottom flange ........................................................................................................... 125Figure 21 Bolt Pattern for the Web Field Splice, shown along the web slope .......................... 126
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LIST OF TABLES
Table 1 Girder G1 Unfactored Shears by Tenth Point ................................................................. 29Table 2 Girder G2 Unfactored Shears by Tenth Point ................................................................. 30Table 3 Girder G1 Unfactored Major-Axis Bending Moments by Tenth Point .......................... 31Table 4 Girder G2 Unfactored Major-Axis Bending Moments by Tenth Point .......................... 32Table 5 Girder G1 Unfactored Torques by Tenth Point .............................................................. 33Table 6 Girder G2 Unfactored Torques by Tenth Point .............................................................. 34Table 7 Section G2-1 Unfactored Major-Axis Bending Moments and Torques ......................... 35Table 8 Section G2-1: Steel Only Section Properties .................................................................. 44Table 9 Section G2-1: 3n=22.68 Composite Section Properties ................................................. 44Table 10 Section G2-1: n=7.56 Composite Section Properties ................................................... 45Table 11 Section G2-2: Steel Only Section Properties ................................................................ 47Table 12 Section G2-2: 3n=22.68 Composite Section Properties with Transformed Deck ........ 47Table 13 Section G2-2: n=7.56 Composite Section Properties with Transformed Deck ............ 48Table 14 Section G2-2: 3nComposite Section Properties with Longitudinal Steel Reinforcement
....................................................................................................................................................... 48Table 15 Section G2-2: nComposite Section Properties with Longitudinal Steel Reinforcement
....................................................................................................................................................... 48Table 16 Unfactored Analysis Results for the Design of Field Splice #1 on Girder G2 ........... 126
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FOREWORD
It took an act of Congress to provide funding for the development of this comprehensivehandbook in steel bridge design. This handbook covers a full range of topics and design
examples to provide bridge engineers with the information needed to make knowledgeable
decisions regarding the selection, design, fabrication, and construction of steel bridges. Thehandbook is based on the Fifth Edition, including the 2010 Interims, of the AASHTO LRFDBridge Design Specifications. The hard work of the National Steel Bridge Alliance (NSBA) and
prime consultant, HDR Engineering and their sub-consultants in producing this handbook is
gratefully acknowledged. This is the culmination of seven years of effort beginning in 2005.
The new Steel Bridge Design Handbookis divided into several topics and design examples as
follows:
Bridge Steels and Their Properties
Bridge Fabrication
Steel Bridge Shop Drawings Structural Behavior
Selecting the Right Bridge Type
Stringer Bridges
Loads and Combinations
Structural Analysis
Redundancy
Limit States
Design for Constructibility
Design for Fatigue
Bracing System Design
Splice Design
Bearings
Substructure Design
Deck Design
Load Rating
Corrosion Protection of Bridges
Design Example: Three-span Continuous Straight I-Girder Bridge
Design Example: Two-span Continuous Straight I-Girder Bridge
Design Example: Two-span Continuous Straight Wide-Flange Beam Bridge
Design Example: Three-span Continuous Straight Tub-Girder Bridge
Design Example: Three-span Continuous Curved I-Girder Beam Bridge Design Example: Three-span Continuous Curved Tub-Girder Bridge
These topics and design examples are published separately for ease of use, and available for free
download at the NSBA and FHWA websites: http://www.steelbridges.org, andhttp://www.fhwa.dot.gov/bridge, respectively.
http://wwwcf.fhwa.dot.gov/exit.cfm?link=http://www.steelbridges.org/http://wwwcf.fhwa.dot.gov/exit.cfm?link=http://www.steelbridges.org/http://wwwcf.fhwa.dot.gov/exit.cfm?link=http://www.steelbridges.org/http://www.fhwa.dot.gov/bridge/http://www.fhwa.dot.gov/bridge/http://www.fhwa.dot.gov/bridge/http://wwwcf.fhwa.dot.gov/exit.cfm?link=http://www.steelbridges.org/8/13/2019 Design Example 06
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The contributions and constructive review comments during the preparation of the handbook
from many engineering processionals are very much appreciated. The readers are encouraged to
submit ideas and suggestions for enhancements of future edition of the handbook to Myint Lwinat the following address: Federal Highway Administration, 1200 New Jersey Avenue, S.E.,
Washington, DC 20590.
M. Myint Lwin, Director
Office of Bridge Technology
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1.0 INTRODUCTIONTub girders are often selected over I-girders because of their pleasing appearance offering asmooth, uninterrupted, cross section. Bracing, web stiffeners, utilities, and other structural and
nonstructural components are typically hidden from view within the steel tub girder, leading to a
clean, uncluttered appearance. Additionally, steel tub girder bridges offer advantages over othersuperstructure types in terms of span range, stiffness, durability, and future maintenance.
Steel tub girders can potentially be more economical than steel plate I-girders in long span
applications due to the increased bending strength offered by their wide bottom flanges, andbecause they require less field work due to handling fewer pieces. Steel tub girders can also be
suitable in short span ranges as well, especially when aesthetic preferences or constructability
considerations preclude the use of other structure types. However, tub girders are typically
designed with a minimum girder depth of 5 feet deep to allow access for inspection, thus limitingtheir efficiency in short span applications.
Tub girders, as closed-section structures, provide a more efficient cross section for resistingtorsion than I-girders. The increased torsional resistance of a closed composite steel tub girder
also results in an improved lateral distribution of live loads. For curved bridges, warping, or
flange lateral bending, stresses are lower in tub girders, when compared to I-girders, since tub
girder carry torsion primarily by means of St. Venant torsional shear flow around the perimeterof their closed sections, whereas I-girders have very low St. Venant torsional stiffness and carry
torsion primarily by means of warping.
The exterior surfaces of tub girders are less susceptible to corrosion since there are fewer details
for debris to accumulate, in comparison to an I-girder structure. For tub girders, stiffeners and
most diaphragms are located within the tub girder, protected from the environment.
Additionally, the interior surface of the tub girder is protected from the environment, furtherreducing the likelihood of deterioration. Tub girder bridges tend to be easy to inspect and
maintain since much of the inspection can occur from inside the tub girder, with the tub serving
as a protected walkway.
Erection costs for tub girders may be lower than that of I-girders because the erection of a single
tub girder, in a single lift, is equivalent to the placement and connection of two I-girders. Tubgirders are also inherently more stable during erection, due to the presence of lateral bracing
between the top flanges. Overall, the erection of a tub girder bridge may be completed in less
time than that of an I-girder counterpart because there are fewer pieces to erect, a fewer number
of external diaphragms to be placed in the field, and subsequently fewer field connections to bemade. This is a significant factor to consider when available time for bridge erection is limited
by schedule or site access.
In many instances, these advantages are not well reflected in engineering cost estimates basedsolely on material quantity comparisons. Consequently, tub girder bridges have historically beenconsidered more economical than I-girder bridges only if their use resulted in a reduction in the
total number of webs in cross section, particularly for straight bridges. However, if regionalfabricators have the experience and equipment to produce tub girders efficiently, the
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competitiveness of tub girders in a particular application can be enhanced. Therefore, the
comparative economies of I- and tub girder systems should be evaluated on a case-by-case basis,
and the comparisons should reflect the appropriate costs of shipping, erection, future inspectionand maintenance as well as fabrication.
Furthermore, designers should not feel limited by overly-strict reading of the AASHTO designprovisions for tub girders in some cases. For example, there are currently cross-sectionallimitations placed on the use of approximate live load distribution factors for straight tub girders
in theAASHTOLRFD Bridge Design Specifications[1]. Limiting the proportions of tub girder
cross-sections solely to allow the use of these approximate live load distribution factors (to allowthe use of simplified analysis methods) may reduce the efficiency and competitiveness of a tub-
girder cross-section. However, these cross-section proportion limitations do not apply when a
refined analysis is employed; thus the use of a refined analysis method allows the designer to
explore additional, and perhaps more economical, design options.
This design example demonstrates the design of a horizontally curved three-span continuous
composite tub girder bridge with a span arrangement of 160-0 210-0 160-0. Thisexample illustrates the flexural design of a section in positive flexure, the flexural design of a
section in negative flexure, computation of distortional stresses, the shear design of the web, the
design of the bottom flange longitudinal stiffener, the design of an internal diaphragm, the design
of a top flange lateral bracing member, the design of a bolted field splice, as well as other designand analysis related topics.
The bridge cross-section consists of two trapezoidal tub girders with top flanges spaced at 10-0on centers, 12-6 between the centerline of adjacent top tub flanges, and 4-0 overhangs for a
deck width of 40-6 out-to-out. For the sake of brevity, only the AASHTO LRFD Strength I
and Service II load combinations are demonstrated in this design example. The effects of wind
loads are not considered. The reader may refer toDesign Example 1: Three-Span ContinuousStraight Composite I-Girder for information regarding additional load combination cases and
wind load effects.
The example calculations provided herein comply with the current AASHTO LRFD Bridge
Design Specifications(5th
Edition, 2010), but the analysis described herein was not performed as
part of this design example. The analysis results and general superstructure details containedwithin this design example were taken from the design example published as part of the National
Cooperative Highway Research Program (NCHRP) Project 12-52 published in 2005, titled
AASHTO-LRFD Design Example: Horizontally Curved Steel Box Girder Bridge, Final
Report [2].
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2.0 OVERVIEW OF LRFD ARTICLE 6.11The design of tub girder flexural members is contained within Article 6.11 of the Fifth Edition oftheAASHTOLRFD Bridge Design Specifications[1], referred to herein as AASHTO LRFD (5
th
Edition, 2010). The provisions of Article 6.11 are organized to correspond to the general flow of
the calculations necessary for the design of tub girder flexural members. Most of the provisionsare written such that they are largely self-contained, however to avoid repetition, some portionsof Article 6.11 refer to provisions contained in Article 6.10 for the design of I-girder sections
when applicable (particularly those pertaining to tub girder top flange design, which is
fundamentally similar to I-girder design). The provisions of Article 6.11 are organized asfollows:
6.11.1 General
6.11.2 Cross-Section Proportion Limits6.11.3 Constructibility
6.11.4 Service Limit State
6.11.5 Fatigue and Fracture Limit State6.11.6 Strength Limit State
6.11.7 Flexural Resistance - Sections in Positive Flexure
6.11.8 Flexural Resistance - Sections in Negative Flexure
6.11.9 Shear Resistance6.11.10 Shear Connectors
6.11.11 Stiffeners
It should be noted that Article 6.11, and specifically Article 6.11.6.2, does not permit the use of
Appendices A and B because the applicability of these provisions to tub girders has not been
demonstrated; however, Appendices C and D are applicable. Flow charts for flexural design of
steel girders according to the new provisions, along with a revised outline giving the basic stepsfor steel-bridge superstructure design, are provided in Appendix C. Appendix C provides a
useful reference for tub girder design. Fundamental calculations for flexural members are
contained within Appendix D.
Example calculations demonstrating the provisions of Article 6.10, pertaining to I-girder design,
are provided in Example 1 for a straight I-girder bridge, and Example 4 for a horizontally curvedI-girder bridge within this Steel Bridge Design Handbook. This design example will highlight
several of the provisions of theAASHTO LRFD (5th
Edition, 2010) as they relate to horizontally
curved tub girder design.
One significant change in the AASHTO LRFD (5th
Edition, 2010) from earlier LRFD
Specifications (prior to third edition) is the inclusion of the flange lateral bending stress in the
design checks. The provisions of Articles 6.10 and 6.11 provide a unified approach for
consideration of major-axis bending and flange lateral bending, for both straight and curvedbridges. Bottom flange lateral bending stresses in tub girders tend to be quite small, due to thewidth of the bottom flange, and can typically be neglected. Top flange lateral bending is caused
by the outward thrust due to web inclination, wind load, temporary support brackets for deckoverhangs, curvature, and from loads applied by the lateral bracing system.
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In addition to providing adequate strength, the constructibility provisions of Article 6.11.3 ensure
that nominal yielding does not occur and that there is no reliance on post-buckling resistance formain load-carrying members during critical stages of construction. The AASHTO LRFD (5
th
Edition, 2010) specifies that for critical stages of construction, both compression and tension
flanges must be investigated, and the effects of top flange lateral bending should be consideredwhen deemed necessary by the Engineer. For noncomposite top flanges in compression,constructibility design checks ensure that the maximum combined stress in the flange will not
exceed the minimum yield strength, the member has sufficient strength to resist lateral torsional
and flange local buckling, and that web-bend buckling will not occur. For noncomposite bottomflanges in compression, during critical stages of construction, local buckling of the flange is
checked in addition to web bend-buckling resistance. For noncomposite top and bottom flanges
in tension, constructibility design checks make certain that the maximum combined stress will
not exceed the yield strength of the flanges during construction.
One additional requirement specified particularly for tub girders sections is in regard to
longitudinal warping and transverse bending stresses. When tub girders are subjected to torsion,their cross-sections become distorted, resulting in secondary bending stresses. Therefore, per
Article 6.11.5, longitudinal warping stresses and transverse bending stresses due to cross-section
distortion shall be considered for:
Single tub girder in straight or horizontally curved bridges
Multiple tub girders in straight bridges that do not satisfy requirements of Article 6.11.2.3
Multiple tub girders in horizontally curved bridges
Any single or multiple tub girder with a tub flange that is not fully effective according tothe provisions of Article 6.11.1.1.
In accordance with Article 6.11.1.1, transverse bending stresses due to cross section distortion
shall be considered for fatigue as specified in Article 6.11.5, and at the strength limit state.Transverse bending stresses at the strength limit state shall not exceed 20.0 ksi. Longitudinal
warping stresses due to cross-section distortion shall be considered for fatigue as specified inArticle 6.11.5, but may be ignored at the strength limit state. Article C6.11.1.1 allows the use of
the beam-on-elastic-foundation (BEF) analogy developed by Wright and Abdel-Samad [3] for
determining the transverse bending stresses and the longitudinal warping stresses due to cross-section distortion. The BEF analogy is discussed in more detail within the calculations provided
in this design example.
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3.0 DESIGN PARAMETERSThe following data apply to this design example:
Specifications: 2010 AASHTO LRFD Bridge Design Specifications, Customary U.S.
Units, Fifth Edition [1]Structural Steel: AASHTO M270, Grade 50W (ASTM A709, Grade 50W) uncoatedweathering steel with Fy= 50 ksi, and conservatively Fu= 65 ksi
Concrete: fc= 4.0 ksi, = 150 pcfSlab Reinforcing Steel: AASHTO M31, Grade 60 (ASTM A615, Grade 60) with Fy= 60 ksi
The bridge has spans of 160-0 210-0 160-0 measured along the centerline of the bridge.
Span lengths are arranged to give relatively equal positive dead load moments in the end spans
and center span. The radius of the bridge is 700 ft at the centerline of the bridge.
The out-to-out deck width is 40.5 ft, and the bridge is to be designed for three 12 ft traffic lanes.
The roadway is superelevated at 5 percent. All supports are radial to the roadway. The framingconsists of two trapezoidal tub girders with the top of the webs in each tub spaced 10 ft apart atthe top of the tub and with a deck span of 12.5 ft between the top of the interior webs of the two
adjacent tubs.
Structural steel having a specified minimum yield stress of 50 ksi is used throughout the bridge.
The deck is a conventional cast-in-place concrete deck, with a specified minimum 28-day
compressive strength of 4,000 psi. The structural deck thickness is 9.5 inches, and there is no
integral wearing surface assumed. The deck haunch is 4.0 inches thick, measured from the topof the web to the bottom of the deck, and is constant throughout the structure. The width of the
haunch is assumed to be 20.0 inches for weight computations.
Shear connectors are provided along the entire length of each top flange, therefore the tub girders
in this example are composite throughout the entire span, including regions of negative flexure.
The shear connectors are 7/8 inch diameter by 6 inches in length. All tub girders (whether
straight or curved) are subject to torsional loading, and the use of shear connectors along theentire length of a tub girder bridge (in both the positive and negative moment regions) is required
to ensure an adequate and continuous load path for St. Venant torsional shear flows along the
entire length of the girder.
Permanent steel stay-in-place deck forms are used between the girders; the forms are assumed to
weigh 15.0 psf since it is assumed concrete will be in the flutes of the deck forms. In this
example, the steel stay-in-place deck forms are used between the top flanges of individual tubgirders and between the top flanges of adjacent girders. Sequential placement of the concrete
deck is considered in this design example.
An allowance for a future wearing surface of 25.0 psf is incorporated in the design. Parapets are
each assumed to weight 495 lb/ft.
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The bridge is designed for HL-93 live load, in accordance with Article 3.6.1.2. Multiple
presence factors are accounted for in the analysis, as specified in Article 3.6.1.1.2 Live load for
fatigue is taken as defined in Article 3.6.1.4. The bridge is designed for a 75-year fatigue life,and single lane Average Daily Truck Traffic (ADTT)SLin one direction is assumed to be 1,000
trucks per day.
The bridge site is assumed to be located in Seismic Zone 1, so seismic effects are not consideredin this design example.
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4.0 GENERAL STEEL FRAMING CONSIDERATIONSComposite tub girder bridges fabricated using uncoated weathering steel have performedsuccessfully without any interior corrosion protection. However, the interiors of tub girders
should always be coated in a light color to aid visibility during girder inspection. Without owner
direction towards a specific coating and preparation, girder interiors should receive a light brushblast and be painted with a white or light colored paint capable of telegraphing cracks in the steelsection. Specified interior paint should be tolerant of minimal surface preparation. At the
Engineers discretion, an allowance may be made for the weight of the paint.
Provisions for adequate draining and ventilation of the interior of the tub are essential. As
suggested in the NSBA Publication Practical Steel Tub Girder Design [4], bottom flange drain
holes should be 1 inches in diameter and spaced along the bottom flanges low side every 50
feet, and be placed 4 inches away from the web plate. Access holes must be provided to allowfor periodic structural inspection of the interior of the tub. The access holes should provide easy
access for authorized inspectors. Solid doors can be used to close the access holes, however they
should be light in weight, and they should be hinged and locked, but not bolted. Wire meshscreens should always be place over copes and clips in end plates, and over the bottom flange
drain holes to prevent entry of wildlife and insects. Wire mesh should be 10 gage to withstand
welding and blasting and have a weave of approximately inch by inch.
Additional detailing guidelines can be found at the AASHTO/NSBA Steel Bridge
Collaborations Website, with particular attention given to document G1.4, Guidelines for
Design Details [5]. Four other detailing references offering guidance include the NSBAPublicationPractical Steel Tub Girder Design[4], the Texas Steel Quality Councils Preferred
Practices for Steel Bridge Design, Fabrication, and Erection [6], the Mid-Atlantic States
Structural Committee for Economic Fabrication (SCEF) Standards, and the AASHTO/NSBA
Steel Bridge Collaboration Guidelines for Design for Constructibility[7].
4.1 Span ArrangementOften, site specific features will influence the span arrangement required. Careful consideration
to the layout of the steel framing is an important part of the design process and involve
alternative span arrangements for the superstructure and substructure cots to arrive at the mosteconomical solution. In the absence of site constraints, choosing a balanced span arrangement
for continuous steel bridges (end spans approximately 80% of the length of the center spans) will
typically provide an efficient design. The span arrangement for this example bridge has spans of
160 feet 210 feet 160 feet. The framing plan of the bridge for this example is shown inFigure 1.
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Figure 1 Framing Plan of the Tub Girder Bridge (all lengths shown are taken along the
centerline of the bridge)
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bending moment in the deck, caused by the cantilever action of the overhang, resulting in
additional deck slab reinforcing for the overhang region of the deck.
In addition, wider deck spans between top flanges can become problematic for several reasons.
Some owners have very economical deck details standards that may not be suited, or even
permitted, for wider decks spans. At the same time, wider deck spans are progressively moredifficult to form and construct. Wider deck spans also limit options for future deck replacementand partial deck removal.
As shown inFigure 2,the example bridge cross-section consists of two trapezoidal tub girders
with top flanges spaced at spaced at 10.0 feeton centers, 12.5 feet between the centerline ofadjacent top flanges with 4.0 feet deck overhangs and an out-to-out deck width of 40.5 feet. The
37.5 feet roadway width can accommodate up to three 12-foot-wide design traffic lanes. The
total thickness of the cast-in-place concrete deck is 9.5 inch including with no integral wearing
surface. The concrete deck haunch is 4 inch deep measured from the top of the web to thebottom of the deck.
Figure 2 Cross Section of the Tub Girder Bridge [2]
4.4 Internal and External Cross-Frame BracingInternal intermediate cross-frames are provided in tub girders to control cross-sectionaldistortion. Cross-sectional distortion is caused by torsional loads that do not act on the tub girderin the same pattern as the St. Venant shear flow, which is uniformly distributed along the
circumference of the tub girder cross-section. Cross-sectional distortion introduces additional
stresses in the tub girder and, therefore, should be minimized. Distortional stresses can beneglected in design if a sufficient number of internal cross-frames with adequate stiffness are
provided. At a minimum internal cross-frames shall be placed at points of maximum moment
within a span and at points adjacent to field splices in straight bridges. Spacing of internal
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4.5 Diaphragms at the SupportsInternal diaphragms at points of support are typically full-depth plate girder sections with a topflange. These diaphragms are subjected to bending moments which result from the shear forces
in the inclined girder webs. If a single bearing is used at the support, and the bearing sole plate
does not span the full width of the girder bottom flange, bending of the internal diaphragm overthe support will result, causing bending stresses in the top flange of the diaphragm and and thebottom flange of the tub girder. Additionally, a torsional moment reaction in the tub girder at the
support will induce a shear flow along the circumference of the internal diaphragm. In order to
provide the necessary force transfer between the tub girder and the internal diaphragms, theinternal diaphragms should be connected to the web and top flanges of the tub girder.
Inspection access at the interior supports must also be provided through the internal diaphragm.
Typically, an access hole will be provided within the internal diaphragm; however care must begiven in determining the location and size of the hole. The Engineer must investigate the flow of
stress at the location of the hole in order to verify the sufficiency of the web near the access hole,
or if reinforcing of the web may be required at the access hole.
Similar to internal diaphragms, external diaphragms are typically full-depth plate girder sections,
but with top and bottom flanges. As acknowledged in the NSBA publicationPractical Steel Tub
Girder Design [4], the behavior of an external diaphragm at a point of support is highlydependent on the bearing arrangement at that location. If dual bearings used at each girder
sufficiently prevent transverse rotation, external diaphragms at the point of support should
theoretically be stress free. The force couple behavior of a dual bearing system resists thetorsion that would otherwise be resisted by the external diaphragm and, in turn, minimizes the
bending moments applied to the external diaphragm.
In accordance with Article 6.7.4.3, full-depth internal and external diaphragms are provided atthe support lines in this design example. The web plates for the internal and external diaphragms
in the three-dimensional analysis are assumed to have a thickness of 0.5 inches. The external
diaphragm top and bottom flanges are assumed to have an area of 8.0 square inches for eachflange. Furthermore, there are no intermediate external braces provided between the tub girders
in this design example.
4.6 Top Flange Lateral BracingIn accordance with Article 6.7.5.3, for horizontally curved tub girders, a full-length lateral
bracing system between common flanges of individual tub sections shall be provided, and thestability of compression flanges between panel points of the lateral bracing system shall be
investigated during the deck placement. Generally, lateral bracing will not be required between
adjacent tub girders.
Top flange lateral bracing creates a quasi-closed section, which increases the torsional stiffness
of tub girder sections during erection, handling, and deck casting. For composite tub girders
closed by the deck slab, the cross-section of the tub is torsionally stiff. However, prior toplacement of the deck slab the open tub is torsionally more flexible and subject to rotation or
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Figure 4 Plan View of a Pratt-type truss lateral bracing system [1]
As shown inFigure 1,a Warren-Type single diagonal top lateral bracing system is used in thisdesign example. The bracing is assumed to be directly connected to the flanges at each internalcross frame and internal top strut, thus the bracing is in the plane of the top flange. The
connection of the top flange lateral bracing directly to the flanges may require wider flanges than
might otherwise be required by design, however this approach may still be more economical
considering the high fabrication cost associated with gusset plates for the connections.
Truss members with an area of 8.0 square inches were assumed for the top flange lateral bracing
members in the three-dimensional analysis. However, design calculations show that a WT9x48.5is required, which has a cross-sectional area of 14.3 square inches. Although not done in this
example, the designer should perform a second iteration of the analysis with the larger cross-
sectional area, as the larger cross-sectional area will affect the load distribution in the bracingsystem in the noncomposite condition.
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5.0 FINAL DESIGN5.1 AASHTO LRFD Limit StatesAASHTO LRFD (5
thEdition, 2010)requires that bridges be designed for specified limit states to
achieve the objectives of constructibility, safety, and serviceability. These objectives are metthrough the strength, service, fatigue and fracture, and extreme-event limit states. These limitstates are intended to provide a safe, constructible, and serviceable bridge capable of carrying the
appropriate design loads for a specified service life. A brief discussion of these limit states is
provided herein, but the reader can refer to Steel Bridge Design Handbook topic on Limit Statesfor more detailed discussion.
5.1.1Strength Limit StateThe strength limit states ensure strength and stability of the bridge and its components under the
statistically predicted maximum loads during the 75-year life of the bridge. The strength limit
states are not based upon durability or serviceability. There are five different strength limit stateload combinations that must be considered by the designer.
In general, Strength I is the load combination used for checking the strength of a component
under normal loading, in the absence of wind. To check the strength of a member or componentunder special permit loadings in the absence of wind, the Strength II load combination is used.
The Strength III load combination is used for checking the strength of a component assuming the
bridge is exposed to a wind velocity exceeding 55 miles per hour in the absence of live load.The Strength IV load combination basically relates to bridges with very high dead-to-live load
force effect ratios. The Strength V load combination is used to check the strength of a
component assuming the bridge is exposed to wind velocity equal to 55 miles per hour under
normal loading.
5.1.2Service Limit StateThe service limit state ensures the durability and serviceability of the bridge and its components
under typical everyday loads, traditionally termed service loads. The AASHTO LRFD (5th
Edition, 2010) includes four service limit state load combinations of which only two are
applicable to steel bridges.
The Service I load combination relates to normal operational use of the bridge and would be used
primarily for crack control in reinforced concrete structures. However, the live load portion of
the Service I load combination is used for checking live load deflection in steel bridges. TheService II load combination only applies to steel superstructures, and is intended to control
yielding of steel structures and slip of slip critical connections due to vehicular live load.
5.1.3Fatigue and Fracture Limit StateThe fatigue and fracture limit state is treated separately from the strength and service limit statessince it represents a more severe consequence of failure than the service limit states, but not
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necessarily as severe as the strength limit states. Fatigue cracking is certainly more serious than
loss of serviceability as unchecked fatigue cracking can lead to brittle fracture, yet many
passages of trucks may be necessary to cause a critically-sized fatigue crack while only oneheavy truck can lead to a strength limit state failure. The fatigue and fracture limit state is only
applicable where the detail under consideration experiences a net applied tensile stress.
The Fatigue I load combination is related to infinite load-induced fatigue life, and the Fatigue IIload combination is related to finite load-induced fatigue life.
5.1.4Extreme Event Limit StateStructural survival of the bridge must be ensured during an extreme event, such as an earthquake,
flood, vessel collision, vehicle collision, or ice flow. The Extreme Event I load combination is
related to earthquake loading, while the Extreme Event II load combination relates to the otherpossible extreme events.
5.1.5Constructibility
Although not a specific limit state, the bridge must be safely erected and have adequate strength
and stability during all phases of construction, as constructibility is one the basic objectives of
theAASHTO LRFD (5th
Edition, 2010). Specific design provisions are given in Articles 6.10.3and 6.11.3 for I- and tub-girders, respectively, to help ensure constructibility. The
constructibility checks are typically performed on the steel section only under the factored
noncomposite dead loads using appropriate strength load combinations, especially whenconsidering the deck placement sequence. Article 3.4.2 provides guidance for the load factors to
use for construction loads.
5.2 Loads5.2.1Dead LoadAs defined in Article 3.5.1, dead loads are permanent loads that include the weight of all
components of the structure, appurtenances and utilities attached to the structure, earth cover,
wearing surfaces, future overlays and planned widenings.
The component dead load (DC) consists of all the structure dead load except for non-integral
wearing surfaces, if anticipated, and any specified utility loads. For composite steel-girder
design, DC is further divided into:
Non-composite dead load (DC1) is the portion of loading resisted by the non-compositesection. DC1represents the permanent component load that is applied before the concrete
deck has hardened or is made composite.
Composite dead load (DC2) is the portion of loading resisted by the long-term compositesection. DC2represents the permanent component load that is applied after the concrete
deck has hardened or is made composite.
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The self weight of the steel girders, cross-frames, diaphragms, lateral bracing and other
attachments is applied to the erected steel structure in the three-dimensional model through the
use of body forces in the various finite elements used to model the structure. A steel density of490 pounds per cubic foot is assumed for all structural steel components. The analysis
assumption requires that the steel be fit and erected in the no-load condition. The steel self-
weight is a non-composite dead load (DC1).
The concrete deck weight is assumed to be placed at one time on the noncomposite steel
structure for the strength limit state checks. A separate deck placement sequence analysis is
performed, where analysis results are used for constructibility checks. The deck placementsequence is discussed later in this section. The deck weight includes the deck and concrete
haunches, as well as an assumed weight of 15 pounds per square foot for the permanent metal
deck forms inside the tub girders and between the two tub girders. The concrete deck weight,
haunch weight, and permanent metal deck form weight are all considered non-composite deadloads (DC1).
The composite dead load (DC2), also referred to as a superimposed dead load, includes theweight of the parapets. The parapets are assumed to weigh 495 pounds per linear foot. The
parapet weight is applied as line loads along the edges of the deck elements in the three-
dimensional analysis.
The component dead load (DW) consists of the dead load of any non-integral wearing surfaces
and any utilities, which can also be considered as superimposed dead loads. DW is applied as a
surface load on the deck in the 3D analysis. For this example, a future wearing surface of 30pounds per square foot of roadway is assumed, but no utilities are included.
For computing flexural stresses from composite dead loads DC2 and DW, the stiffness of the
long-term composite section in regions of positive flexure is calculated by transforming theconcrete deck using a modular ratio of 3n (Article 6.10.1.1.1b). In regions of negative flexure,
the long-term composite section is assumed to consist of the steel section plus the longitudinal
reinforcement within the effective width of the concrete deck (Article 6.10.1.1.1c).
5.2.2Deck Placement SequenceThe deck is considered to be placed in the following sequence for the constructibility limit state
design checks, which is also illustrated in Figure 5. The concrete is first cast from the left
abutment to a location near the dead load inflection point in Span 1. The concrete between
approximate dead load inflection points in Span 2 is cast second. The concrete beyond theapproximate dead load inflection point to the abutment in Span 3 is cast third. Finally, the
concrete over the two piers is cast. In the analysis, earlier concrete casts are made composite for
each subsequent cast.
For the constructibility limit state design checks, the noncomposite section is checked for themoments resulting from the deck placement sequence or the moments computed assuming the
entire deck is cast at one time, whichever is larger.
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The deck load is assumed to be applied through the shear center of the interior girders in the
analysis. However, the weight of the fresh concrete on the overhang brackets produces lateral
force on the flanges of the exterior girders. This eccentric loading and subsequent lateral forceon the flanges must be considered in the constructibility limit state design checks.
Figure 5 Diagram showing deck placement sequence
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5.2.3Live LoadLive loads are assumed to consist of gravity loads (vehicular live loads, rail transit loads andpedestrian loads), the dynamic load allowance, centrifugal forces, and braking forces. Live loads
illustrated in this example include the HL-93 vehicular live load and a fatigue load, with the
appropriate dynamic load allowance and centrifugal force (see Section5.3)effects included.
Influence surfaces are utilized to determine the live load force effects in this design example.
More details regarding influence surfaces and the live load analysis associated with the 3D
analysis model are provided in Section6.1.2 of this example.
Live loads are considered to be transient loads applied to the short-term composite (n) section.
For computing flexural stresses from transient loading, the short-term composite (n) section in
regions of positive flexure is calculated by transforming the concrete deck using a modular ratioof n(Article 6.10.1.1.1b). In regions of negative flexure, the short-term composite (n) section is
assumed to consist of the steel section plus the longitudinal reinforcement within the effective
width of the concrete deck (Article 6.10.1.1.1c), except as permitted otherwise for the fatigueand service limit states (see Articles 6.6.1.2.1 and 6.10.4.2.1).
When computing longitudinal flexural stresses in the concrete deck (see Article 6.10.1.1.1d), due
to permanent and transient loads, the short-term composite section should be used.
Design Vehicular Live Load (Article 3.6.1.2)
The design vehicular live load is designated as the HL-93 and consists of a combination of thefollowing placed within each design lane:
a design truck ordesign tandem.
a design lane load.
The design vehicular live load is discussed in detail within Example 1 of the Steel Bridge DesignHandbook.
Fatigue Load (Article 3.6.1.4)
The vehicular live load for checking fatigue consists of a single design truck (without the laneload) with a constant rear-axle spacing of 30 feet (Article 3.6.1.4.1). The fatigue live load is
discussed in detail within Example 1 of the Steel Bridge Design Handbook.
5.3 Centrifugal Force ComputationThe centrifugal force is determined according to Article 3.6.3. The centrifugal force has two
components, the radial force and the overturning force. The radial component of the centrifugalforce is assumed to be transmitted from the deck through the end cross frames or diaphragms and
to the bearings and the substructure.
The overturning component of centrifugal force occurs because the radial force is applied at adistance above the top of the deck. The center of gravity of the design truck is assumed to be 6
feet above the roadway surface according to the provisions of Article 3.6.3. The transverse
spacing of the wheels is 6 feet per Figure 3.6.1.2.2-1. The overturning component causes the
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exterior (with respect to curvature) wheel line to be more than half the weight of the truck and
the interior wheel line to be less than half the weight of the truck by the same amount. Thus, the
outside of the bridge is more heavily loaded. The effect of superelevation, which reduces theoverturning effect of centrifugal force, is considered, as permitted by Article 3.6.3. Figure 6
shows the relationship between the centrifugal force and the superelevation effect. The
dimensions denoted bysand hinFigure 6 are both equal to 6 feet.
Figure 6 Vehicular Centrifugal Force Wheel-Load Reactions
Article 3.6.3 states that the centrifugal force shall be taken as the product of the axle weights ofthe design truck or tandem and the factor C, taken as:
Rg
vfC
2
Eq. (3.6.3-1)
where:
f = 4/3 for load combinations other than fatigue and 1.0 for fatiguev = highway design speed (ft/sec)g = gravitational acceleration = 32.2 ft/sec
2
R = radius of curvature of traffic lane (ft)
Use the average bridge radius, R = 700 ft in this case. For the purpose of this design example,
the design speed is assumed to be 35 mph = 51.3 ft/s. Therefore, for the HL-93 Design Truck:
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156.0
7002.32
3.51
3
4C
2
The next step is to compute the wheel load reaction, RCL and RCR, due to centrifugal force
effects, as shown inFigure 6. In the case of the design truck, the wheel spacing, s, and the heightof the radial force, h, are both equal to 6.0 feet. Therefore, summing moments about Point A
(Figure 6)and enforcing equilibrium, the wheel load reactions, RCLand RCRare simply equal to
C multiplied by W, as follows:
W156.0WC
cos2
s2
coshW)(CRR
CRCL
where:
W = axle weight (kips)
RCLis an upward reaction for the left wheel, and RCRis an equal but opposite downward reactionfor the right wheel.
As permitted by Article 3.6.3, the effects of superelevation on the individual wheel loadreactions can be computed and combined with the centrifugal force effects. For the 5% deck
cross slope, the angle is equal to:
= tan-1
(0.05) = 2.86
The wheel load reactions due to superelevation, RSLand RSR, as shown inFigure 7,are computed
by summing the moments about the left wheel, as follows:
0.550W
2.86cos6
W)sin(2.8662.86cos2
6
scos
Whsincos2
s
RSR
RSL= 1.0W - RSR= 1.0W 0.550W = 0.450W
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Figure 7 Effects of Superelevation of the Wheel-Load Reactions
For a refined analysis, as used in this design example, unit wheel load factors can be computed
based on the sum of the wheel load reaction due to the centrifugal force and superelevation
effects. The unit wheel load factors are applied to the appropriate wheels in the analysis. Unit
wheel load factors due to the combined effects of centrifugal force and sueperlevation can becomputed for the left wheels, FL, and the right wheels, FR. The sum of FLand FRmust equal 2.0,
as there are two wheel loads per one axle. The left and right unit wheel load factors, FLand FR,are computed as follows:
212.1W
W450.0W156.00.2
W
RR0.2F
SLCL
L
788.0W
W550.0W156.00.2
W
RR0.2F
RLCR
R
As shown inFigure 8,FLand FRrepresent the factors that must be multiplied by the left wheel
and right wheel load, respectively, in the analysis to take into account the combined effects of
both centrifugal force and superelevation. In this case, since FLis greater than FR, the outermostgirder will receive a slightly higher load and the innermost girder will receive slightly lower load
from the design truck. Therefore, it is also necessary to compute the condition with no
centrifugal force, i.e., a stationary vehicle, and select the worst case. In the live load analysisperformed for this design example, force effects from an analysis due to live load cases with
centrifugal force effects included (FLequals 1.212 and FRequals 0.788) are compared to force
effects due to cases with no centrifugal force effects included (FL and FR equal 1.0), and themaximum/minimum force effect is selected.
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From Table 3.4.1-1 (minimum load factors of Table 3.4.1-2 are not considered here):
Strength I x [1.25(DC) + 1.5(DW) + 1.75((LL + IM) + CE + BR) + 1.2(TU)]Strength III x [1.25(DC) + 1.5(DW) + 1.4(WS) + 1.2(TU)]
Strength V x [1.25(DC) + 1.5(DW) + 1.35((LL + IM) + CE + BR) + 0.4(WS) + 1.0(WL) +
1.2(TU)]Service I x [DC + DW + (LL + IM) + CE + BR + 0.3(WS) + WL + 1.2(TU)]Service II x [DC + DW + 1.3((LL + IM) + CE + BR) + 1.2(TU)]
Fatigue I x [1.5((LL + IM) + CE)]
Fatigue II x [0.75((LL + IM) + CE)]
where:
= Load modifier specified in Article 1.3.2DC = Dead load: components and attachments
DW = Dead load: wearing surface and utilities
LL = Vehicular live loadIM = Vehicular dynamic load allowance
CE = Vehicular centrifugal force
WS = Wind load on structure
WL = Wind on live loadTU = Uniform temperature
BR = Vehicular braking force
In addition to the above load combinations, a load combination is included for the
constructibility limit state defined in Article 3.4.2 as follows:
Construction Strength I: x [1.25(DC) + 1.5(C) + 1.25(WC)]
where:
DC = Dead load
C = Construction live loads
WC = Wind load for construction conditions from an assumed critical direction.Magnitude of wind may be less than that used for final bridge design.
In this design example, it has been assumed that there is no equipment on the bridge during
construction and the wind load on the girders is negligible.
For the purpose of this example, it has been assumed that the Strength I load combination
governs for the strength limit state, so only Strength I loads are checked in the sample
calculations for the strength limit state included herein. Also, the load modifier, , is assumed tobe 1.0 throughout this example unless noted otherwise. Furthermore, from a separate analysis,
the girder demands due to thermal loading are determined to be quite small, and are neglected
throughout these computations.
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6.0 ANALYSISArticle 4.4 of the AASHTO LRFD (5
th Edition, 2010) requires that the analysis be performed
using a method that satisfies the requirements of equilibrium and compatibility, and utilizes
stress-strain relationships for the proposed materials. Article 4.6.1.2 provides additional
guidelines for structures that are curved in plan. The moments, shears, and other force effectsrequired to proportion the superstructure components are to be based on a rational analysis of theentire superstructure. Equilibrium of horizontally curved I-girders is developed by the transfer of
load between the girders, thus the analysis must recognize the integrated behavior of structural
components. Equilibrium of curved tub girders can be somewhat less dependent on theinteraction between girders, as there are typically fewer external bracings between adjacent tub
girders as compared to I-girder bridges.
Furthermore, in accordance with Article 4.6.1.2, the entire superstructure, including bearings, isto be considered as an integral structural unit in the analysis. Boundary conditions should
represent the articulations provided by the bearings and/or integral connections used in the
design.
In most cases, small deflection elastic theory is acceptable for the analysis of horizontally curved
steel girder bridges. However, curved girders, especially I-girders, are prone to deflect laterally
when the girders are insufficiently braced during erection, and this behavior may not beappropriately recognized by small deflection theory. In curved tub girder bridges, there is
typically sufficient bracing provided during steel erection so that deflections do not invalidate the
use of small deflection elastic theory.
In general, three levels of analysis exist for horizontally curved girder bridges: approximate
methods of analysis, 2D (two-dimensional) methods of analysis, and 3D (three-dimensional)
methods of analysis. The V-load method and the M/R methods are approximate analysis methodthat are typically used to analyze curved I-girder bridges and curved tub girder bridges,
respectively. Both methods are developed based on the understanding of the distribution of
forces through the curved bridge system. The two primary types of 2D analysis models are thetraditional grid (or grillage) model and the plate and eccentric beam model. In 2D analysis
models, the girders and external cross frames and diaphragms are modeled using beam elements,
with nodes in a single horizontal plane. A 3D model recognizes the depth of the superstructure,as the girders are modeled using a plate or shell element for the girder webs and internal and
external diaphragm webs, and all internal and external cross frame members are modeled using
truss type elements. Two planes of nodes are typically used on each girder, one in the plane of
the top flange and the second in the plane of the bottom flange. Further details regarding thesemethods of analysis can be found in the Steel Bridge Design Handbook topic on Structural
Analysis.
6.1 Three-Dimensional Finite Element AnalysisA three-dimensional finite element analysis is used to analyze the superstructure in this design
example. The girder webs and bottom flanges are modeled using plate elements. The top flangesof each tub girder are modeled with beam elements. The girder elements connect to nodes that
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are placed in two horizontal planes, one plane at the top flange and one plane at the bottom
flange. The horizontal curvature of the girders is represented by straight elements that have
small kinks at the nodes, rather than by curved elements. Nodes are placed on all flanges alongthe girder at each internal cross frame and top flange lateral bracing location, and typically at the
middle of each top flange lateral bracing bay.
The composite deck is modeled using a series of eight-node solid elements attached to the girdertop flanges with beam elements, which represent the shear studs.
Bearings are modeled with dimensionless elements called foundation elements. Thesedimensionless elements can provide six different stiffnesses, with three for translation and three
for rotation. If a guided bearing is orientated along the tangential axis of a girder, a stiffness of
zero would be assigned to the stiffness in the tangential direction. The stiffness of the bearing,
and supporting structure if not explicitly modeled, would be assigned to the direction orthogonalto the tangential axis.
Internal cross frame members are modeled with individual truss elements connected to the nodesat the top and bottom flange of the girders. Internal solid-plate diaphragms at the supports are
modeled with a single plate element. External solid-plate diaphragms at the supports are
modeled using three full depth plate elements along the length of the diaphragm, and three beam
elements placed at the top and bottom of the web representing the top and bottom flanges of thediaphragm. Since the plate and beam elements are isoparametric three elements are used to
model the web and flanges of the external diaphragm to allow for the possibility of reverse
curvature.
Top flange lateral bracing members are modeled with individual truss elements connected to
nodes at the top flanges of the tub girders.
6.1.1Bearing Orientation and ArrangementThe orientation and lateral restraint of bearings affects the behavior of most girder bridges formost load conditions, and is particularly true for curved and skewed girder bridges.
Furthermore, in tub girder bridges on or two bearings can be use at each tub girder at each
support.
The use of two bearings to support an individual girder at a support allows the girder torsion to
be directly removed through the force couple provided by the bearings, and reduces the reaction
demand in the bearings. Two bearing systems typically work well with radial supports, but areimpractical with supports skewed more than a few degrees where the tub girder and/or
diaphragms stiffness work against uniform bearing contact during various stages of girder
erection and deck slab construction [4].
The use of one bearing to support an individual girder at a support optimizes contact between thegirder and the bearing. One bearing systems also tend to be more forgiving of construction
tolerances and, for skewed supports one bearing systems are demonstrably better than two
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bearing systems [4]. A disadvantage of one bearing systems is that stiff cross frames or
diaphragms between girders are required to resolve the girder torsion into the bearings.
In this example, two bearings are used at each girder support location. The centerline of each
bearing is located 28.5 inches from the girder centerline at the support. Furthermore, the
bearings at Pier 1 are assumed fixed against translation in both the radial and longitudinaldirections (Fixed Bearing). The bearings at the abutments and Pier 2 are assumed fixed againstradial movement but free in the longitudinal direction (Guided Bearing). The longitudinal
direction at each support varies, as in this case the longitudinal direction is taken along a straight
line chord line between fixed support (Pier 1) and each expansion bearing. Curved girderbridges do not expand and contract along the girder line, but more so along the aforementioned
chord lines. Orientating the bearings in the manner discussed significantly reduces the
longitudinal stresses in the girders that can occur due to thermal loading. Therefore, due to the
bearing orientation and from a separate analysis, the girder demands due to thermal loading aredetermined to be quite small, and are neglected throughout these computations. In all designs
the thermal demands must be considered and properly addressed.
6.1.2Live Load AnalysisThe use of live load distribution factors is typically not appropriate for curved steel tub girder
bridges, because these structures are best analyzed as a system. Therefore, influence surfaces aremost often utilized to more accurately determine the live load force effects in curved girder
bridges. Influence surfaces are an extension of influence lines, such that an influence surface not
only considers the longitudinal position of the live loads, but the transverse position as well.
Influence surfaces provide influence ordinates over the entire deck. The influence ordinates are
determined by applying a series of unit vertical loads, one at a time, at selected longitudinal and
transverse positions on the bridge deck surface. The magnitude of the response for the unitvertical load is the magnitude of the ordinate of the influence surface for the particular response
at the point on the deck where the load is applied. The entire influence surface is created by
curve fitting between calculated ordinates. Specified live loads are then placed on the surface,mathematically, at the critical locations (maximum and minimum effects), as allowed by the
governing specification. The actual live load effect is determined by multiplying the live load by
the corresponding ordinate. In the case of an HL-93 truck load, a different ordinate will probablyexist for each wheel load. The total HL-93 truck live load effect is the summation of all the
wheel loads times their respective ordinate.
In curved girder bridges, influence surfaces are generally needed for all live load force results,such as major-axis bending moment, minor-axis bending moments, girder shear, reactions,
torques, deflections, cross frame forces, diaphragm forces, lateral bracing forces, etc.
Unless noted otherwise, all live load force effects in this example are computed using influencesurfaces, developed using the three-dimensional analysis. The dynamic load allowance (impact)is included in the analysis, and is applied in accordance with Article 3.6.2 for strength, service,
and fatigue as required. Multiple presence factors are also included within the analysis, and thus
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are incorporated into the analysis results. Also, as appropriate, centrifugal force effects are also
included in the analysis, using wheel load factors as shown in Section5.3 of this design example.
6.2 Analysis ResultsThis section shows the results from the three-dimensional analysis of the superstructure.Analysis results are provided for the moments, shears, and torques for girders G1 and G2. Allanalysis results are unfactored. Live load results included multiple presence factors, dynamic
load allowance (impact), and centrifugal force effects.
Specific analysis results for design Section G2-1, which is located approximately 57 feet from
the centerline of the bearings at abutment 1, are provided in Table 7. The analysis results are
used in the design computations associated with Section G2-1, provided later within this design
example.
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Table 2 Girder G2 Unfactored Shears by Tenth Point
Note: Reported shears are the vertical shears and are for major-axis bending plus torsion in the critical
tub girder web.
DC1STEEL DC1CONC DC2 DW Pos. Neg. Pos. Neg.
(ft) (kip) (kip) (kip) (kip) (kip) (kip) (kip) (kip)
0 0.00 31 110 39 52 128 -26 61 -12
1 16.26 19 74 17 22 110 -29 52 -12
2 32.51 11 44 11 15 93 -35 44 -12
3 48.77 5 21 6 8 75 -44 36 -12
4 65.03 -7 -26 -3 -5 54 -52 25 -18
5 81.29 -11 -45 -6 -8 40 -67 18 -27
6 97.54 -17 -69 -12 -16 36 -85 13 -34
7 113.80 -24 -97 -17 -23 33 -102 12 -43
8 130.06 -29 -117 -22 -29 26 -114 7 -49
9 146.31 -35 -137 -27 -35 16 -127 4 -53
10 162.57 -46 -185 -41 -55 13 -155 4 -61
10 0.00 47 185 44 58 160 -14 65 -4
11 21.34 32 130 28 37 135 -22 55 -4
12 42.68 26 105 22 29 120 -33 49 -9
13 64.01 17 69 15 20 100 -42 41 -13
14 85.35 12 46 7 10 78 -46 33 -16
15 106.69 0 0 0 0 57 -57 24 -24
16 128.03 -12 -46 -7 -10 46 -78 16 -33
17 149.36 -17 -69 -15 -20 41 -99 13 -41
18 170.70 -26 -105 -22 -29 33 -120 9 -50
19 192.04 -32 -130 -28 -37 22 -135 4 -55
20 213.38 -47 -185 -44 -58 14 -159 4 -64
20 0.00 46 185 41 55 158 -14 64 -4
21 16.26 35 137 27 35 128 -15 53 -4
22 32.51 29 117 22 29 115 -26 49 -7
23 48.77 24 97 17 23 102 -33 41 -12
24 65.03 17 69 12 16 85 -36 33 -13
25 81.29 11 45 6 8 67 -40 27 -18
26 97.54 7 26 3 5 52 -54 18 -25
27 113.80 -5 -21 -6 -8 44 -75 12 -36
28 130.06 -11 -44 -11 -15 34 -93 12 -44
29 146.31 -19 -74 -17 -22 28 -111 12 -52
30 162.57 -31 -110 -39 -52 26 -129 12 -61
Girder G2 Unfactored Shears
10th
Point
Span
Length
Dead Load LL+I Fatigue LL+I
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Table 3 Girder G1 Unfactored Major-Axis Bending Moments by Tenth Point
DC1STEEL DC1CONC DC2 DW Pos. Neg. Pos. Neg.
(ft) (kip-ft) (kip-ft) (kip-ft) (kip-ft) (kip-ft) (kip-ft) (kip-ft) (kip-ft)
0 0.00 0 0 0 0 0 0 0 0
1 15.74 521 2191 340 450 2472 -469 748 -98
2 31.49 882 3666 592 785 4330 -938 1252 -196
3 47.23 1049 4321 724 960 5412 -1408 1477 -293
4 62.97 1047 4320 734 972 5863 -1878 1545 -385
5 78.71 851 3503 620 821 5777 -2338 1502 -471
6 94.46 493 2043 387 514 5189 -2795 1367 -553
7 110.20 -75 -315 36 47 4109 -3915 1108 -667
8 125.94 -837 -3461 -434 -576 2602 -4547 714 -813
9 141.69 -1781 -7206 -1014 -1343 1252 -5559 270 -991
10 157.43 -2969 -11629 -1762 -2335 1061 -7784 231 -1249
10 0.00 -2969 -11629 -1762 -2335 1061 -7784 231 -1249
11 20.66 -1422 -5845 -802 -1062 1310 -4411 363 -810
12 41.33 -326 -1516 -95 -125 2993 -3033 924 -618
13 61.99 493 1881 425 563 4784 -2275 1324 -470
14 82.65 977 3900 733 972 5926 -2008 1556 -367
15 103.31 1118 4442 836 1108 6304 -1749 1616 -279
16 123.98 976 3900 733 972 5928 -2013 1556 -369
17 144.64 492 1880 424 562 4775 -2279 1326 -471
18 165.30 -327 -1519 -95 -127 3000 -3021 923 -616
19 185.96 -1422 -5848 -803 -1064 1315 -4421 381 -810
20 206.63 -2969 -11633 -1762 -2336 1062 -7788 233 -1230
20 0.00 -2969 -11633 -1762 -2336 1062 -7788 233 -1230
21 15.74 -1780 -7203 -1014 -1345 1248 -5556 270 -997
22 31.49 -837 -3459 -436 -577 2591 -4532 714 -810
23 47.23 -74 -312 34 46 4099 -3900 1107 -665
24 62.97 493 2044 386 511 5181 -2783 1367 -551
25 78.71 851 3504 618 819 5769 -2328 1502 -462
26 94.46 1047 4320 732 971 5855 -1868 1544 -378
27 110.20 1048 4321 723 958 5405 -1402 1477 -286
28 125.94 882 3666 591 784 4326 -993 1252 -191
29 141.69 521 2189 339 449 2470 -466 748 -96
30 157.43 0 0 0 0 0 0 0 0
Girder G1 Unfactored Major-Axis Bending Moments
10th
Point
Span
Length
Dead Load LL+I Fatigue LL+I
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Table 4 Girder G2 Unfactored Major-Axis Bending Moments by Tenth Point
DC1STEEL DC1CONC DC2 DW Pos. Neg. Pos. Neg.
(ft) (kip-ft) (kip-ft) (kip-ft) (kip-ft) (kip-ft) (kip-ft) (kip-ft) (kip-ft)
0 0.00 0 0 0 0 0 0 0 0
1 16.26 555 2268 351 465 2606 -484 796 -95